A chunk of Mars might soon return home
A piece of a meteorite called Sayh al Uhaymir 008 (SaU008) is being prepared to be carried on board NASA’s Mars 2020 rover mission, now being built at the agency’s Jet Propulsion Laboratory in Pasadena, California. This chunk will serve as target practice for a high-precision laser on the rover’s arm.
Mars 2020’s goals build upon the work of its predecessors: Collect samples from the Red Planet’s surface so that a future mission could potentially return samples back to Earth. One of the rover’s many tools will be a laser designed to illuminate rock features as fine as a human hair.
That level of precision requires a calibration target to help tweak the laser’s settings. Previous NASA rovers have included calibration targets as well. Depending on the instrument, the target material can include materials made of rock, metal or glass, and can often look like a painter’s palette.
But working on this particular instrument sparked an idea among JPL scientists: why not use an actual piece of Mars? Earth has a limited supply of Martian meteorites, which scientists determined were blasted off Mars’ surface millions of years ago.
These meteorites aren’t as unique as the geologically diverse samples 2020 will collect. But they’re still scientifically interesting — and perfect for target practice.
“We’re studying things on such a fine scale that slight misalignments, caused by changes in temperature or even the rover settling into sand, can require us to correct our aim,” said Luther Beegle of JPL. Beegle is principal investigator for a laser instrument called SHERLOC (Scanning Habitable Environments with Raman and Luminescence for Organics and Chemicals) via an agency-issued release. “By studying how the instrument sees a fixed target, we can understand how it will see a piece of the Martian surface.”
When it arrives on the surface of the Red Planet, SHERLOC will be the first instrument to use Raman and fluorescence spectroscopies, scientific techniques familiar to forensics experts. Whenever an ultraviolet light shines over certain carbon-based chemicals, they give off the same characteristic glow that you see under a black light.
Scientists can use this glow to detect chemicals that form in the presence of life. SHERLOC is designed to photograph the rocks it studies, then map the chemicals it detects across those images. That adds a spatial context to the layers of data Mars 2020 will collect.
“This kind of science requires texture and organic chemicals — two things that our target meteorite will provide,” said Rohit Bhartia of JPL, SHERLOC’s deputy principal investigator.
No Flaky Meteorites
To select the right one for SHERLOC, JPL turned to contacts at NASA’s Johnson Space Center in Houston, as well as the Natural History Museum of London. Not just any Martian meteorite would do: its condition would need to be solid enough that it would not flake apart during the intensity of launch and landing.
It also needed to possess certain chemical features to test SHERLOC’s sensitivity. These had to be reasonably easy to detect repeatedly for the calibration target to be useful.
Experts tried several samples, cutting off thin bits to test whether they would crumble. Using a “flaky” sample could damage the entire meteorite in the process.
The SHERLOC team ultimately agreed on using SaU008, a meteorite found in Oman in 1999. Besides being more rugged than other samples, a piece of it was available courtesy of Caroline Smith, principal curator of meteorites at London’s Natural History Museum.
“Every year, we provide hundreds of meteorite specimens to scientists all over the world for study,” Smith said. “This is a first for us: sending one of our samples back home for the benefit of science.”
SaU008 will be the first Martian meteorite to have a fragment return to the planet’s surface — though not the first on a return trip to Mars.
NASA’s Mars Global Surveyor included a chunk of a meteorite known as Zagami. It’s still floating around the Red Planet onboard the now-defunct orbiter.
Additionally, the team behind Mars 2020’s SuperCam instrument will be adding a Martian meteorite to their own calibration target.
Preparing for Humans on Mars
Along with its own Martian meteorite, SHERLOC’s calibration target will include several interesting scientific samples for NASA’s human space flight efforts. These include materials that could be used to make spacesuit fabric, gloves and a helmet’s visor.
By watching how they hold up under Martian weather, including radiation, the space agency should be able to test these materials for future Mars missions.
“The SHERLOC instrument is a valuable opportunity to prepare for human spaceflight as well as to perform fundamental scientific investigations of the Martian surface,” said Marc Fries, a SHERLOC co-investigator and curator of extraterrestrial materials at Johnson Space Center. “It gives us a convenient way to test material that will keep future astronauts safe when they get to Mars.”
Christopher Paul has had a lifelong interest in spaceflight. He began writing about his interest in the Florida Tech Crimson. His primary areas of interest are in historical space systems and present and past planetary exploration missions. He lives in Kissimmee, Florida, and also enjoys cooking and photography. Paul saw his first Space Shuttle launch in 2005 when he moved to central Florida to attend classes at the Florida Institute of Technology, studying space science, and has closely followed the space program since. Paul is especially interested in the renewed effort to land crewed missions on the Moon and to establish a permanent human presence there. He has covered several launches from NASA's Kennedy Space Center and Cape Canaveral for space blogs before joining SpaceFlight Insider in mid-2017.